Liquid dispensing apparatus



R E L X E R T R R.

Filed April 18, 1939 LIQUID DISPENSING APPARATUS Bec., 4, E945. l R. R. TREXLER LIQUID DISPENSING APPARATUS Filed April 1B, 1959 12 Sheets-Sheet 2 GRLLNS C061' INVEN JET Mcha/z7 MR@ @wf 77100@ ATTORNEY R. R. TRL-:XLER 2,390,136 LIQUID DIsPENsING APPARATUS Filed April 18, 1939 l2 Sheets-Sheet 5 Dec 4, 1945- R. R. TREXLER 2,390,136 LIQUID DIsPENsING APPARATUS l Filed April 18, 1939 12 Sheets-Sheet 4 ATToRn/Ens,

Dec. 4, 1945. R. R. TRExLl-:R

LIQUID DISPENSING APPARATUS l2 Sheets-Sheet 5 Filed April 18, 1959 INVENTOR lie/dez' BY 'c/mzzi @et #f7/va ATToRNEY.

/f L TOTAL, v

n /7`I r l Dc. 4, 1945. v R. R. TRExLER 2,390,136

LIQUID DISPENS ING APPARATUS Filed April 1a, 1939 12 sheets-sheet 6 I 134 INVENTOR, 159 ckazwjleler 7 176 ATTQRNEYs` Dec. 4, 1945. R. R. TRl-:xLER 2,390,1364

LIQUID DISPENSING APPARATUS Filed April 18, 19:59 12. sheets-sheet 'r NTOR ZT ATTORNEY 5 INVE j? EC BY:

PRICE PERGRL.

Dec. 4, 1945.

R. R. TREXLER` LIQUID DISPENSING APPARATUS 12 Sheets-Sheet 8 Filed Apyrl 18, 1939 INVENTOR. /za/f'dR/ezfef ATTORNEY5- I 12 Sheets-Sheet 9 wv l E6, O p-.. l wf n v A fw M i w .d w n W my ,A w v W R. R. TREXLER LIQUID DI'SPENS-ING APPARATUS Dec.4, 1945.

File@ April 18, 1939 Turm.l

y cnLLoNs k EU] PRacE PER CRL.

l l n l l I l l l f l f f l i Dec. 4, 1945. R. R. TREXLER 2,390,136

LIQUID DISPENSING APPARATUS I Filed April 18, 1959 12 sheets-sheet io .l ein lNvENToR I Yz' chafa/ rexlez ATTORNEYS Dec. 4, 1945. R. R. TRl-:xLER

LIQUID DISPENS ING APPARATUS 12 Sheets-Sheet 1l Fild April 18, 1939 E m ma VENTOK hardFezZaZ? JWTTORNEY.

R. R. TRExLER 2,390,136

LIQUID DISPENSING APPARATUS v Filed April 18, 1939 12 Sheets-Sheet 12 m. m W1.

,.iqf M -1 1- Il crm.. l: :m i l l l//l/l//I//l//l//l/l/l//l/l//l// Dec. 4, 1945.

Patented Dec. 4, 1945 UNITED STATES PATENT oFFlcE 22 Claims.

This inventionrelates to liquid dispensing apparatus, and more particularly to apparatus of Y.

the type adapted to dispense gasoline or the like.

It is an object of the invention to provide improved liquid dispensing apparatus of the type wherein the movements of the liquid propelling pump may be made directly proportional to the actual liquid flow within the dispensing line whereby the pump itself may be used to actuate the register mechanism or other recording orl indicating elements of the apparatus, meter mechanisms or the like being eliminated. accordance with the invention the liquid propelling pump for propelling liquid through the dispensing line is operated from `a constantly operating power source, such as an electric motor; and instantaneously operable and readily controllable means is provided for instantaneously diverting from the pump all or any predetermined amount of the motor power when it is desired to reduce the pump speed or stop the pump during dispensing operations. By this means the movements of the liquid propelling pump are rendered accurately proportional to the ow of liquid propelled thereby, whether the pump be operated at full speed, part speed, or intermittently. l

More specifically, one of the objects of the invention contemplates the provision of improved means for controlling the power diverting mchanism which diverts the power between the power source and the dispensing pump, whereby to insure a total diverting of power, a, partial diverting of power, or no diverting of power as may be required. y

A further object of the invention is' to provide an improved form of power diverting mechanism, readily adapting itself to various types of control.

Another object of the invention is to provide means for absorbing shock to the column of liquid within the dispensing line upon the stopping ofthe dispensing iiow.

Another object of the invention is to lprovide, in liquid dispensing apparatus of the type above set forth, improved and readily controllable means for causing the dispensing of liquid at partial rates of ow.

Another object of the invention is to provide improved by-pass means for by-passing liquid from the outlet back to the inlet side of the dispensing pump whereby to calibrate the same. In one form of the invention the by-pass means is operable only during operation of the pump, and proportional to pump displacement.

Another object of the invention is to provide in liquid dispensing apparatus of the type stated, means for disconnecting the register or other indicating or recording mechanism from the pump when liquid is not being dispensed, whereby to insure accuracy of the registering, indicating or recording means.

A still further object of the invention4 is to provide in dispensing apparatusof the type above set forth, improved forms of pumping means' in which the slippage factor is reduced or eliminated whereby to simplify the required form of power diverting mechanism.

Still further objects, advantages and features of the invention will be apparent from the following speciflcation when taken in connection with the accompanying drawings wherein certain preferred embodiments and modifications of the invention are illustrated. l

In the drawings, wherein like reference numerals refer to like parts throughout:

Fig. l is a general assembly view, partly in section, of a liquid dispensing apparatus constructed in accordance with one form of the invention.

Fig. 2 is a partial detail view of the by-pass valve for the power diverting mechanism, taken onthe line 2-2 of Fig. 1.

Fig. 3 is a partial detail view of the control valve operating means for the diverting mechanism.

Fig. 4 is adetail sectional view of a preferred form of control valve, as used in the embodiment of the invention illustrated in Fig. 1.

Fig. 5 illustrates a modiiied form of control valve operating means omitting the toggle mechanism for insuring the full opening of the control valve.

Fig. 6 illustrates a modified form of control valve.

Fig. 7 is a general assembly view' showing an electrical form of control valve operating means.

Fig. 8 is a partial detail view of the mechanism shown in Fig. 7.

Fig. 9 illustrates a modied form of electrical y control.

Fig. 10 is a detail view of the control means shown in Fig. 9.

Fig. 11 illustrates a form of the invention wherein the control valve for the power diverting means is arranged at the dispensing nozzle.

\ Fig. l2 is a detail view of the control valve and associated nozzle construction as used in the embodiment of the invention shown in Fig. 11.

Fig. 13 is a sectional view of the mechanism of Fig. 14 illustrates a modiiled form of control valve and nozzle assembly. l

Fig. 15 is a view similar to Fig. 12 illustratin a generally similar form of mechanism, but wherein the nozzle valve for the dispensing line is eliminated.

Fig. 16 illustrates a form o'f the invention gen.- erally similar to that shown in Fig. 11, but employing a. modified form of control circuit for the power diverting mechanism.

Fig. 17 is a detail view of the nozzle assembly and associated control valve as used in the mechanism shown in Fig. 16.

Fig. 18 is a sectional view of the structure shown in Fig. 17, taken on the line I8-I8 thereof.

Fig.19 is a detail view of the valve mechanism for controlling the by-pass means for the dispensing pump, in accordance with one form of the invention.

Fig. 20 illustrates a form of the invention wherein a Bowden wire or the like is used for operating the control valve for the power diverting mechanism.

Fig. 21 is a detail view of the nozzle valve and associated parts as used in the form of invention shown in Fig. 20.

Figs. 22, 23 and 24 are views generally similar f to Fig. 21, but illustrating modified forms of nozzle constructions. f

Fig. 25 shows a form of control valve particularly adapted for use with the type of nozzle construction shown in Fig. 24.

Fig. 26 is a view illustrating a form of the invention wherein a fluid pressure line leading from the dispensing nozzle is utilized for operating the control valve for the power diverting mechanism.

Fig. 27 isv a detail View illustrating the nozzle construction and associated parts as embodied in the structure of Fig. 26.

Fig. 28 illustrates a form of the invention wherein the control valve for the power diverting mechanism is controlled conjointly by dispensing line pressure and a nozzle-operated Bowden wire.

Fig. 29 is a detail view of the operating mechanism for the construction shown in Fig. 28.

Fig. 30 is a detail view of the dispensing pump by-pass means as embodied in the construction shown in Fig. 28. g,

Fig. 31 is a detail sectional view of the by-pass valve taken on the line 3I-3I of Fig. 30.

Fig. 32 illustrates a form of the invention wherein the control valve for the power diverting mechanism is controlled by the volume of liquid iiow within the dispensing line.

Figs. 33 and 34 are detail views of the control mechanism as embodied in the structure of Fig. 32, Fig. 34 being `taken on the line 34-34 of Fig. 33.

Fig. 35 is a partial detail view of the structure shown in Fig. 32, but modified to include dispensing line surge absorbing means.

Fig. 36 illustrates a form of the invention wherein the control valve for the power diverting mechanism is conjointly operated by the volume of ilow and the pressure conditions Within the dispensing line.

Figs. 37 and 38 are detail views of the operating mechanism embodied in the Fig. 36 structure, Fig. 38 being taken on the line 38-38 of Fig. 37.

Fig. 39 illustrates a form of the invention wherein means is provided for disconnecting the register mechanism from the dispensing pump when no liquid is being dispensed.

Figs. 40 and 41 are detail views of the control mechanism for the disconnecting means, Fig. 41 being taken on the line 4I-4I of Fig. 40.

Fig. 42 is a detail view of the disconnecting mechanism as embodied in the structure of Fig. 39.

Figs. 43 and 44 are detail views illustrating a modified form of disconnecting means, Fig. 44

being taken on the line "-44 of Fig. 43.

Fig. 45 illustrates a form of the invention embodying improved dispensing pumping means and a simpliiied form of control for the power diverting mechanism.

Fig. 46 is a detail view of the pumping means shown in Fig. 45 and taken on the line 46--46 thereof.

Fig. 47 is a detail view illustrating the cylinder structure of the pumping means.

Figs. 48 and 49 illustrate modiiled forms of cylinder structure.

Fig. 50 is a detail view of the adjusting means which may be used for adjusting the pump displacement. taken on the line 50-50 of Fig. 46, and l Fig. 51 is a general assembly view illustrating a form of apparatus embodying the control means of Figs. 11, 12 and 13, but including a pump by-pass structure as shown in Figs. 28, 30 and 3l, a register disconnecting mechanism as shown in Figs. 39 to 42 inclusive, and a form of pump structure as illustrated in Figs. 45, 46, 47 and 50.

This application is a continuation-in-part of my copending application Serial No. 237,593, filed October29, 1938, now issued as Patent No. 2,239,- 207, dated April 22, 1941.

Referring ilrst to Figs. 1 to 4 inclusive, and Fig. 19, the embodiment of the invention illustrated comprises a dispensing apparatus housing 5 associated with an underground tank or reservoir 6 adapted to receive the liquid to be dispensed. In the particular embodiment illustrated this liquid, which is indicated by the reference numeral 1, may be gasoline or the like. The tank is provided with an inlet pipe, not shown, closed by the usual cap, by means of which the gasoline is introduced into the underground tank. The tank is also provided with an air release pipe 8.

An outlet pipe 9 leads from the tank, from a point near the bottom thereof, to the inlet side of a main liquid propelling pump I0, which may in this instance be some suitable form of accurate gear pump. The outlet side of the pump is connected to a dispensing line II, I2, I3 which leads to a sight glass or other suitable flow indicator I4. The outlet side of the sight glass is connected to a flexible hose I5 which terminates in a dispensing nozzle I6 controlled by a hand operated valve I1 in the usual manner. The dispensing nozzle is adapted to be supported upon a hose hook I8 when not in use, as shown in Fig. 1. A check valve I9 is provided in the dispensing line between pipes II and I2, and a bypass or bleeder line 20 controlled by an adjustable valve 2I leads around the pump as shown The liquid propelling or dispensing pump I0 is adapted to be driven by an electric motor 24 controlled by means of switch mechanism 25. This switch mechanism may be operated by means of operating devices 26 and 21 associated with the hose support I8 in the usual manner. 'I'he electric motor is adapted to operate constantly during the entire dispensing operation, after the dispensing nozzle has been removed from the hose hook and until it is" returned thereto, whereas the dispensing pump is adapted to operate only while liquid is actually being dispensed and at such speed as will give the proper rate of liquid flow. `To this end the motor is arranged to drive the pump through a power diverting mechanism which'comprises a differential gearing 28 supported by a suitable support bracket 29, and an associated control circuit 30 operated by the differential gearing and controlled by the liquid pressure in the dispensing line I2, I3. More specifically, the electric motor drives the main ring gear 3| of the differential by means of suitable beveled gearing 32 and 33. Ring gear 3l is secured to the housing of the differential and rotates therewith. The housing carries a stub shaft 34 upon which the differenor the auxiliary pump 4I, or both. Obviously other suitable forms of differential gearings, such as planetary differential gearings, may be substituted for the form of gearing specifically shown.

The auxiliary gear pump, which may be any form of inexpensive gear pump and preferably smaller than the dispensing pump Ill, is arranged to circulate liquid in the control circuit 30. This control circuit comprises a main pipe orA conduit dcontrolled by a control valve 43, and a by-pass pipe 44 controlled by a bypass valve 45. When the control valve 43 is open, the auxiliary pump is free to circulate the liquid within the control circuit, but when the control valve is closed, the auxiliary pump is locked against operation. The by-pass valve 85 is a springcontrolled relief valve and is adapted to be adjusted so that a small amount of the liquid will be passed therethrough in the event the control valve 43 is quickly closed when the auxiliary pump is operating, to thereby absorb the shock of the locking operation.

The by-pass valve is illustrated in detail in Fig. 2, and the control valve and its operating mechanism is shown in Figs. 3 and 4. Referring rst to Fig. 2, the by-pass valve 45 comprises a housing 86 carrying a valve seat 41 against which a ball 138 is adapted to be urged by means of a compression spring 69. The tension in the spring, and consequently the pressure at which the by-pass valve may be set to open, is adjustable by means ofan adjusting screw 50 which is adapted to adjust the length of the compression spring from its upper end.

As seenin Figs. 3- and 4, the control valve 43 preferably comprises a valve casing 5I having a cylindrical central chamber adapted to receive a cylindrical valve core member 52. The core member is slidable within the cylindrical chamber under the control of an upstanding stem 53 which is threadedly secured to the core member and adapted to be operated by operating mechanism later to be described. The valve casing is provided with annular channels 54 and 55 in communication with the pipes 42 of the control v.

circuit, and the core member 'is provided with passageways 56 and 51 in communication with the channels, and with a passageway 58 connecting the passageways 56 and 51. When the core member is in the position shown in Fig. 4, free liquidcommunication is provided between the pipes 42, by means of the core passageways 56, 51 and 58, but when the core member is raised to bring the passageways A56 and 51 above the casing channels 54 and 55 communication is cut oif.- If the core member is partly raised, part communication between pipes 42 will be maintained. By reason of the annular channels 54 and 55, the fluid pressure upon the sides of the core member is balanced at all times so that there is no resultant side thrust of the core member against the valve casing. Accordingly the core member is freely operable at all times. Passageways 59 and 68 lead from the passageways 56 and 51 to the chambers. formed within the valve casing at the ends of the core member to prevent liquid locking of the core member. A' packing nut 6I prevents leakage of liquid outwardly from the valve along the stem 53.

The mechanism for operating the control valve, as best shown in Fig. 3, comprises a pressure device 63` responsive to the pressure in the dispensing vline I2, I3. Specifically this pressure responsive device comprises a casing 64 attached to and communicating with a pipe 65 leading from the dispensing line. Within the casing is a flexible bellows 66, which may be of any suitable construction. The bellows is'secureql, as by soldering or the like, at its lower end 61 to the casing 64, and at its upper end 68 to a plate member 69 attached' to the valve operating rod 53 and arranged for sliding movement within a bearing formed in the lower end of the casing 64. A compression springlll surrounds shaft 53 and normally urges the shaft and the plate 69 upwardly. Openings`1| in the casing prevent air-lock of the bellows. As liquid pressure is introduced into the casing 64 by means of pipe 65, the bellows 66 will be collapsed against the force of spring 10 moving the valve control stem 53 downwardly to the Fig. 4 position, thus opening the control valve 43. A release of liquid pressure within casing 64 causes compression spring 10 to raise valve stern 53, thus closing the lcontrol valve 43.

As shown in Fig. 19, the valve 2| for controlling the by-pass line 20 around the dispensing pump may be any suitable form of adjustable needle Avalve and, as illustrated, comprises a valve casing 12 formed with chambers 13 and 14 communicating by means of a passage 15. A needle valve stem 16 threaded into a packing plug 11 and operable by means of a knob 18 adjustably controls the valve passageway 15.

The main liquid propelling or dispensing pump I0 is arranged to actuate the registering or recordingelements of the apparatus by means of a gearing 8D driven by the pump, and a flexible shaft 8|. By means ofi driving connections 82, 83 and 84 the shaft 8I is adapted to operate a volume register 85. The shaft 8| is also adapted to operate a total price or cost register 86 by means of driving connections 81 and 88. Interposed between the shaft 8I and the gearing 81 is a suitu able variator mechanism 89 by which the gear ratio between the shaft and the cost register 86 may be changed whereby to compute the cost of the dispensed gasoline 'at different unit prices. This variator mechanism may be any suitable form of change speed gearing. The registers and their operating parts may likewise be of any suitable desired type, for example, of the type shown in the patent to E. J. Svenson, for Liquid han`- dling mechanism, Patent No. 2,117,750, dated May 17, 1938.

In operation, the liquid to be dispensed, as gasoline, is introduced into the underground storace tank or reservoir by means of the usual i111- ing pipe. During this operation the displaced air within the tank is exhausted through the air release pipe 8 exhausting underneath the dispensing apparatus. To eiect a dispensing operation, the operator removes the dispensing nozzle from the hose hook I8 and manipulates switch '25 to start the electric motor 24 which thereafter runs constantly during the dispensing operation. As a result of the previous dispensing operation, fluid pressure has been built up in the dispensing line I2, I3. 'I'his iluid pressure maintains the bellows 66 collapsed against the pressure of spring 10 so that the control valve 43 is open. Accordingly as the motor 24 is 'started and while the nozzle valve I'I still remains closed, auxiliary pump 4I is operated through the differential mechanism. and the main dispensing pump I remains stationary. The auxiliary pump circulates the liquid in the closed circuit through the open valve 43. The valve being in `fully open position, there is no impedance to the flow of the liquid within the closed circuit, and no driving force or drag is transmitted back through the differential to the dispensing pump I0. In other words, even though the motor 24 is operating, no driving force is transmitted to the dispensing pump.

vAs the operator now opens the nozzle valve I1 to dispense liquid, the pressure within the dispensing line I2, I3 is relieved. This causes the relief of the fluid pressure within the casing 64 of the pressure responsive device 63, and the compression spring operates to expand the bellows 66, closing control valve 43. As the control valve closes, the circulation of the liquid Within the closed control circuit 30 is stopped. This locks the auxiliary pump 4| from operation and the driving force from the motor 24 is immediately transmitted to the dispensing pump III.` The dispensing pump operates and liquid is dispensed from the nozzle I6. In view of the fact that the control valve 43 may be closed rapidly by the relief of pressure Within the dispensing line I2, I3, the by-pass valve 45 is provided to relieve the shock upon the pumps and the differential mechanism as the auxiliary pump is stopped. To this end the adjusting screw 50 of the by-pass valve is so set that a small quantity of the liquid may be circulated through the by-pass line 44 as the control valve 43 is rst closed. The adjustment of screw 50 is such that circulation through bypass line 44 is normally prevented, and the bypass valve opens only for a very short time and only upon the rapid closing of control valve 43, to prevent any shock to the operating parts of the system.

When it is desired to cut off the ilow of the dispensed liquid, the operator closes valve I1. 'I'his builds up pressure within the dispensing line I2, I3, causing the opening of control valve 43. The dispensing pump I0 stops and the auxiliary pump 4I begins its operation to circulate the liquid freely within the closed control circuit. The operator may open kor close the nozzle valve I 'I at will to accurately control the quantity of liquid dispensed, and each time as the nozzle valve is closed, the driving force upon the dispensing pump III is immediately relieved by reason of the opening o! control valve 43. Accordingly there is no tendency to drive the dispenshas been stopped by the nozzle valve. Accuracy is assured and maintained.

Should the operator desire to dispense liquid at some fractional rate of now, he closes nozzle valve I1 partially.. This causes a partial building up of pressure within the dispensing line I2, I3, resulting in a partial operation of the pressure control device 63 and in a partial opening of control valve 43. Under these circumstances, therefore, both pumps I0 and 4I will be operated at reduced speed from the power source or motor 24. Equilibrium within the system is always maintained, and the rate of liquid flow from the dispensing nozzle will be proportional to the degree of opening of the nozzle valve. The tension o1' spring I0 is such that the bellows will not be collapsed by normal dispensingr pressures in the line I2, I3, as when the nozzle valve is fully opened. However, if the nozzle valve is partially closed, a pressure slightly above normal is produced in the dispensing line, and this increased pressure causes the partial opening of control valve 43. The adjustment of the parts may be accurately controlled in view oi' the fact that the control valve 43 is freely operable at all times and not iniluenced by pressure conditions within the control circuit 30. During fractional rate dispensing flow, the pressures'within the dispensing line are built up only very slightly above normal. Accordingly the dispensing pump I0 operates against a substantially constant pressure at all rates of delivery, to further maintain and assure accuracy. inasmuch as the movements oI.' the dispensing pump I0 are thus maintained accurately proportional to the actual volume of liquid dispensed, Whether the ow be at full rate, fractional rate or intermittent, the dispensing pump may be directly .connected to the register devices of the apparatus. Metering mechanisms or devices are eliminated.

When the dispensing operation is completed, the operator restores the dispensing nozzle to the hose hook I8 and shuts 01T the electric motor.

The check valve I9 prevents reverse ow within the dispensing line and insures the maintenance of pressure Within pipes I2 and I3 after the dispensing pump is stopped. The by-pass line 20, which leads around the dispensing pump from the outlet to the inlet side thereof, is provided for Calibrating the pump for accuracy. the amount of liquid which is by-passed through the line 20 during operation of the pump being accurately controllable by the valve 2 I. It is to be understood that the by-pass line 2U is merely a calibrating means and may be eliminated if the calibration of the pump is unnecessary or the pump struc- A ture includes Calibrating means for providing Preferably the mechanism also includes means for insuring the full opening of the control valve for the power diverting mechanism as liquid pressure is built up to a predetermined point within the dispensing line l2, |8 whereby to insure the complete unloading of the control circuit at the end oi the dispensing operation. To this end the rod or stem 53 for operating the control valve is pivotally connected, as indicated at 90, with a toggle mechanism comprising apair of toggle links 9| connected by a tension spring 92, the outer ends of the links being guided in their movements by a slotted, xed guide bar 93. It will be seen that as the stem 53 is propelled downwardly upon the building up of pressure within the pressure' device 63, as the stem reaches a predetermined position, the toggle links 9| will snap past dead center tending to assume their dotted line position and insuring full downward or opening movement oi' the valve stem. In other words, after the toggle links pass dead center, the tension of spring 92 aids the liquid pressure within casing 89 to insure full valve opening. However, as the liquid pressure within casing 04 is released upon the opening of the nozzle valve I1, the spring 92 is not sumciently strong to resist spring 10 causing upward movement oi valve stem 53 to l close the control valve.

In Fig. 5 a control arrangement is illustrated omitting the toggle mechanism.

In Fig. 6 an embodiment is illustrated wherein the control valve for the control circuit 30 of the power diverting mechanism is of the type which is iniluenced b'y the liquidpressure within the control circuit pipe d2. In this instance the valve comprises a casing 95 provided with chambers 96 and 91. A valve member 98 having its stem threaded into a plug 99 is arranged for controlling the communication through the valve between chambers 90 and 91. The valve stem may be operated by means of a gear |00 in mesh with rack teeth |0I provided upon the stem or shaft 53 of the pressure device 63. If the upper pipe 42 is the inlet pipe to the valve casing, the valve member 98 must be closed against the liquid pressure within the control circuit 30. On the other hand if the lower pipe 42 is the inlet to the valve casing, the liquid pressure within the control circuit tends to close valve member 98. A control valve of this type, which is influenced by the liquid pressure within the control circuit as distinguished from the type of control valve shown in Fig. 4, may .in certain installations be desired.

In'Figs. 7 and 8 an embodiment ofthe invention is illustrated which is generally similar to that previously described except that the control valve for the control circuit of the power diverting mechanism is electrically operated, and means may be provided in the dispensing line for absorbing the surge or shock of the liquid as the liquid ow is rapidly stopped.

In this instance the pressure device 63 controls a switch |05 which in turn controls an electromagnet |90 for operating the control valve which may be of any suitable form and as illustrated is adapted for rack operation. To this end the valve is provided with a gear |01 adapted to be operated by a rack |08 provided on the core |09 of the electromagnet. As best shown in Fig. 8, a compression spring |I0 embraces the magnet core |09 and normally urges the core downwardly into the position shown in Figs. 7 and 8, in which position valve 43 will be open.

In the operation of this form of the invention when pressure exists within the dispensing line I2, I3 and within the pressure device 63, switch |05 is open and no current is transmitted to the electromagnet |06. Accordingly the compression switch 25 as shown in Fig. '7 so that the electromagnet can be energized onlyl after the nozzle support I8 has been raised to start the motor 24 and eiect a dispensing operation. If the control valve is of the type shown in Fig. 6, such as valve 95, and wherein liquid pressure within the control circuit 30 tends to open the valve, then the power of the electromagnet may be so proportioned to the liquid'pressure exerted upon the valve that the valve can be held partially open by the liquid pressure even when the electromagnet is energized, thereby permitting partial rate dispensing with the electromagnet in energized condition.

The surge absorbing device indicated at I|2` is shown in section in Fig. 16. It may comprise an air-lilled dome member II3 connected to the dispensing line by means of a pipe II4. A flexible diaphragm of rubber or the like I I5 separates the dome from the liquid within pipe I| 4, but as pressure builds up within the dispensing line, the flexible diaphragm will expand into the dome compressing the air therein. The dome thus acts as a surge chamber for absorbing` liquid pressure shocks within the dispensing line.

In Figs. 9 and 10 an varrangement is shown for operating the control valve of the control cir-l cuit conjointly by mechanical and electrical means. In this instance a control valve 43 of the type shown in Fig. 4 is preferably used, but the valve stem 53 is extended downwardly through the valve, forming the core of an electromagnet H1. Valve stem 53 is also provided with a switch contactor IIB adapted to engage switch contacts H9 for controlling the current vto the electromagnet.

In operation when liquid is being dispensed and there is no build up of pressure within the dispensing line I2, I3 and within the pressure device 63, valve stem 53 will be in its raised position holding control valve 43 closed. As the nozzle valve is closed and pressure builds up within the dispensing line, valve stem 53 will be moved downwardly opening control valve 43. 'At a predetermined position during this opening movement switch contacts H8, H9 will be closed and electromagnet l.I I1 will be energized, and as the electromagnet is energized the valve stem core 53 will be pulled downwardly the full extent of its movement insuring the complete opening of the valve. The switch contacts H9 are suiilciently flexible to allow for the movement of contactar I8 after the closing of the switch. In this form of the invention it will be seen that the control valve is primarily mechanically under the control of the pressure device 63, but the electrical means is provided, similar to the toggle mechanism described with reference to Fig. 5, for insuring the complete opening of the control valve as the nozzle valve in the dispensing line is closed. When the nozzle valve is opened'and pressure within the dispensing line is relieved, the electromagnet |I1 does not have sufficient strength to resist the raising of the valve stem 5,3 by the spring 10 within the pressure device.

In Figs. 11, 12 and 13 an embodiment of the invention is illustrated wherein the control circuit for the power diverting mechanism is extended outwardly to the dispensing line nozzle, and the control valve for the control circuit is formed at the nozzle as a part thereof. In this instance the control circuit 30 comprises a. pipe |20 leading from the dispensing line I2 to the auxiliary pump 4|. A pipe conduit |2| leads from the pump outwardly along the dispensing line terminating at the dispensing nozzle, the outer portion of the conduit as indicated at |22 being constructed of flexible .tubing and secured to the dispensing hose as shown. A by-pass pipe 44 and Spring pressed relief valve 45 form a bypass between pipes |20 and. |2| as in the previously described embodiments of the invention.

Fig. 14 illustrates a modied form of nozzle construction, as compared with that shown in Figs. 12 and 13, which nozzle construction is also usable with the form of control circuit illustrated in Fig. 11. Inasmuch as the nozzle structure of Fig. 14 is of the simpler `construction, its structure and mode of operation will be first described. In Fig. 14 the dispensing nozzle |8 comprises the usual nozzle valve |23 normally urged into closed position by compression springf|24 and adapted to be opened by the valve stem |25 operable by lever |29. In accordance with the invention the upper end of stem |25 is threadedly secured to a cylindrical valve core member |21 slidable within a valve casing member |28 formed as a part'of the nozzle structure, the valve member |21 being adapted to control the ow of liquid from the conduit |22. To this end the casing |28 is provided with an annular channel |29 communicating with conduit |22, and the valve core |21 is provided with passages |30 adapted to connect the channel with main chamber |3| of the nozzle. Valve core |21 is also provided with passages |32 connecting with the chamber formed at the end of the valve to prevent fluid-lock thereof. A nondrain valve |34 urged into closed position by a light compression spring |35 may be provided in the nozzle assembly on the outlet side of the nozzle valve-|23.

In the operation of this form of construction as the motor 24 is started, and before the actuation of the nozzle lever |26 auxiliary pump 4| will be operated and the main dispensing pump I will remain stationary. Liquid will be drawn from the dispensing line |2 by the auxiliary pump through pipe |20 and discharged by conduit |2| back into the dispensing line at the nozzle end thereof. At this time control valve |21 and nozzle valve |23 are in the position shown in Fig.`

14 permitting the free discharge-of liquid from conduit |22 into the dispensing line, but preventing the delivery of liquid from the spout |6a of the nozzle. During this operation of the parts the hose line I5 and the dispensing line |2 act as the return line for the control circuit 30, no gasoline is being dispensed and there is no actuation either of the dispensing pump I0 or the register mechanism. As dispensing lever |26 is now operated, nozzle valve |23 will be opened, and dispensing of gasoline will take place when control valve |21 has been sufficiently closed to cause a building up of pressure within the differential mechanism, which pressure starts the main dispensing pump I0, causing gasoline to be dispensed through the open nozzle valve |23 and overcoming the non-drain valve |34. Liquid may be dispensed at full or partial rates of flow, the arrangement being such that valve |23 is open wnen valve |21 is closed and vice versa, both stem |25, and an outer part |38 loosely mounted on the valve stem and adapted to be opened when the projecting portion |39 thereof is. engaged by a shoulder |40 provided on stern |25. A compression spring |4| urges the outer valve part |38 into closed position, and a second compression spring |42 urges the valve stem |25 and the inner valve |31 into closed position. The control valve |21 is provided with two sets of passageways |43 and |44 in communication with the channel |29, passageways |43 being larger than passageways |44.

In operation nozzle lever |29 may be partially operated to cause the partial shifting of valve stem |25 to effect partial rate dispensing, or fully operated to eiect full rate dispensing. The partial shifting of valve stem |25 opens the inner dispensing valve |31 and cuts off communication of control valve passageways |43 with the channel |29. Passageways |44 remain in communication with the channel permitting partial operation of auxiliary pump 4|. The complete shifting of valve stem |25 opens both valves |31 and |38 and completely closes the control valve |21. By proper proportioning the size of valves |31 and |38 with .respect to passageways |43 and |44, the pressure against which the dispensing pump l0 will be pumping at partial and full rates of delivery may be controlled and equalized for accuracy.

In Fig. 15 an arrangement is shown substantially similar to that illustrated in Figs. 12 and 13, but wherein the nozzle valve is eliminated. the non-drain valve |34 being relied upon to prevent inadvertent dispensing of liquid. The control valve |21 is provided with large and small passageways |43 and |44 as before, adapting it for partial flow control. A compression spring |45 urges the valve stem into the position shown in Fig. 15. When the control valve |21 is in the position shown in Fig. 15, the auxiliary pump 4| is free to operate and no power is transmitted to the dispensing pump I0. The non-drain valve |34 will prevent inadvertent dispensing of liquid even though no nozzle valve is provided. As the valve stem |25 is actuated, partial or full rate dispensing will be effected in the manner previously described, the movements of the main dispensing pump |0 being entirely controlled from the control valve |21.

In Figs. 16, 17 and 18 an embodiment is illustrated generally similar to that shown in Fig. 11 except that the liquid control circuit 30 is entirely independent of .the dispensing line, permitting the use of liquid in the control circuit other than that which is being dispensed. In

this instance the conduits |41 and |48 forming the inlet and outlet sides of the control circuit are both extended by means of flexible tubings |49 andv |50 out to the dispensing nozzle. The control valve 21 operable by the nozzle valve stem |25 is provided with passages |5|, |52 and |53 adapted to form communication between channels |54 and |55 connected to tubings |49 the valve. l The outer valve is urged into closed and |50 respectively. Packing |56 prevents leakage between the control circuit and the dispensing line. In this instance the non-drain valve |34 may be arranged on the approach side of the dispensing valve |23 as there is never any reverse flow in the dispensing line. The operation of this form of construction is believed to be clear from what has been previously set forth.

tion of the sheath being secured to the dispensing i hose I5 for movement therewith. The nozzle end of the Bowden wire |58 is pivotally secured as indicated at |60 to a lever |6| rigidly fixed to nozzle valve operating lever |26. A compression spring |62 normally urges valve stem 53 downwardly. A

In operation control valve 43 is normally open when nozzle valve |23 is closed, as stated, but as nozzle lever 26 is actuated to open the dispensing valve |23, the Bowden wire is simultaneously pulled against the force of spring |62 causing the closing of the control valve 43. Dispensing at partial rates of flow may be effected by moving the nozzle operating lever to a corresponding intermediate position.

In Figs. 22,623, 24 `and 25 modified forms of Bowden wire control are shown. In Fig. '22, an arrangement substantially similar to that shown in Fig. 21 is provided except that no nozzle valve is incorporated in the structure, the control valve 43 being solely relied upon to control the movements of the dispensing pump I0 as has been previously described. In Fig. 23 the arrangement is like that shown in Fig. 21 except that the nozzle valve |23 closes against the flow of liquid within the dispensing line, rather than with the flow. The valve stem |25 slides within a bearing |63 formed on a nozzle cap member |64, the stem normally being urged into closed position or to the left as seen in Fig. 23 by a compression spring |65. Stem |25 carries a pair of collars |66 and |61, valve |23 being loosely mounted 0n the stem and normally urged into engagementwith collar |66 by a compression spring |68 which' bears against the valve and against the collar |61. In operation, as valve stem |25 is moved to the right by actuation of lever |26, valve |23 will be opened in the usual manner by collar |66, but on the closing movement of the valve, valve |23 is free to separate momentarily from the collar 66, compressing the spring |68. 'Ihe operation of the parts is otherwise the same as previously described. This form of nozzle valve which closes against the fluid now, produces less shock in the fluid line upon valve closing. Obviously itcan be used with any of the embodiments of the invention previously described, and is not limited to Bowden wire control.

Fig. 24 illustrates a double nozzle valve structure, similar to Fig. 12, adapted for Bowden wire control. The inner valve |10 is secured to the valve stem |25 and is normally urged into closed position by a spring I1|. The outer valve |12 is loose on the valve stem and carries a projection |13 adapted to be engaged by shoulder |14 formed on the valve stem whereby the stem may open position by a spring |15. As the valve stem |26 is shifted vto the right, the inner valve 10 will first be opened, permitting partial flow, and thereafter the outer valve |12 will be opened, permitting full flow, as describedin reference to Fig. 12.

Fig. 25 illustrates a form of control valve well adapted for use with the construction of Fig. 24. The valve is generally similar to that illustrated in Fig. 4 except that the passages in the valve core which communicate with the channels 54 and 55 comprise large passages |18 and small passages |11. The action of the valve is the same as described with reference to Fig. 13. Obviously this form of valve can be substituted for a valve such as shown in Fig. 4 wherever this may be desirable.

Figs. 26 and 27 illustrate an embodiment of the invention wherein a liquid pressure line, controllable from the dispensing nozzle, is utilized for operating the control valve 43. Referring particularly to Fig. 27, a flexible, liquid-containing conduit |80 is adapted to be secured to the dispensing hose I5 for movement therewith. The

nozzle end of the conduit terminates within a secured to a. rod |86 pivotally connected to a bell-crank lever |81 mounted upon a pivot |88. A link |89 connects the bell-crank with a lever |88 fixed to the nozzle operating handle |26. The opposite end of the conduit |80 terminates within a casing |9| This casing carries a ilexible bellows |92 secured at its upper end to a piston plate member |93 and at its lower end to the casing as indicated at |94. Plate member |93 is. secured to the valve stem 53. A compression spring |95 normally urges plate |93 upwardly. In operation as nozzle actuating lever |26 is actuated to open nozzle valve |23, rod |86 will be simultaneously depressed by actuating linkage |90, |89 and |81.

Downward movement of rod |86 causes the compression of bellows |8| forcing liquid through conduit |80 into the casing |9|. The iluid pressure within casing |9| causes the collapse of bellows |92 forcing valve stern 53 downwardly. In this instance the control valve 43 will be so arranged that it is closed upon downward movement of the 280 operable within the xible sheath 20| is arranged at its nozzle end for operation from the nozzle lever |26 in the manner previously 'described with reference to Figs. 20 and 21. The

opposite end of the Bowden wire is secured to a lever 202 pivoted as indicated at v2 03 toa frame bracket 204. A tension spring 205 normally pulls the Bowden wire downwardly as seen in Fig. 29.

y'I'he valvestem 53 is provided with a collar 206 adapted to be engaged by the lever 202, the upper end of the valve stem being connected with the pressure device 53 in the manner previously described with reference to Fig. 3.

' In operation the control valve 43 is controlled from the pressure device 63 as described in 'connectlon with the embodiment of the invention shown in Figs. 1 to 4 inclusive, the valve stem 53 being lowered to open the control valve as pressure is built up in the dispensing line and 'raised to close the valve as the pressure within the dispenslng line is relieved. When the nozzle valve is open, lever 202 will be raised completely free of collar 206 by the Bowden wire causing valve stem 53 to be under the control of the pressure device 63 as just described. However, as the nozzle valve is closed, spring 205 pulls the lever 202 downwardly into the position shown inA Fig. 29 causing the lever to engage collar 206 and insure the full downward opening movement of the control valve 43. In other words, the control valve is primarily under the control of the pressure device 63, but the Bowden wire control provides additional means for insuring that the control valve will be completely opened -at the end. of the dispensing operation.

Referring to Figs. 28, 30 and 3l, there is illustrated a modiiled form of by-pass or Calibrating arrangement for lthe dispensing pump wherein the amount of liquid which is by-passed around the pump will be directly proportional to the volume of liquid dispensed. To this end the bypass line 20 is provided with a valve 2I0 controlled from and in accordance with the movements of the check valve I9. The valve member 2II of check valve I9 is rigidly connected with an arm 2I2 pivotally connected to a` link 2I3 which is in turn pivotally connected to a lever 2I4 secured to the stem 2I5 of the valve 2I0. The valve stem 2I5 is threaded into a plug 2I6, the arrangement being such that the valve stem may be operated by the arm 2I4 to open or close communication between the inlet and outlet valve chambers. A tension spring 2I'l normally urges lever 2I4 upwardly to close both the check valve I9 and the by-pass valve 2I0.- However,4`

. to the volume of liquid dispensed through the dispensing line, insuring that the by-pass line 20 will by-pass a xed or predetermined percentage of the dispensed liquid regardless of the dispensing rate. Further, when the check valve I9 is closed, the by-pass valve 2I 0 will also be closed. 'Ihe amount 4which the valve 2I0 will be opened by the check valve may be varied to accurateltr calibrate the pump by moving the pivot connection 2 I'l outwardly or inwardly along the slot 2I8 of the lever 2I2. The slot 2I9 in link 2I3 permits adjustment of the pivot point with respect to the link whereby t insure that valve 2 I0 will be closed when check valve I9 is closed in all positions of the pivot 2I'I along the slot 2I8.

In Figs. 32, 33 and 34 an embodiment of the invention is illustrated wherein the control valve for the power diverting mechanism is actuated and controlled by the rate or volume of liquid dow within the dispensing line. The dispensing line I2 is provided with a. check valve 220 arranged. adjacent th'e' liquid control circuit 30. The check valve has a valve member 22|v which is opened by the liquid flow through the dispensing line, the opening of the valve being proportional to the rate or volume of flow. Valve member 22| has rigidly secured thereto a sector member 222 in toothed engagement with'the gear wheel 223 fixed to the end of a valve stem member 224. The stem 224 is threaded into a plug 225 provided as a part of the casing of the control valve 226. A tension spring 221 normally pulls the sector upwardly into the position shown in Fig. 33 wherein the check valve member 22! is in closed position. Thel core member 220 of the control valve is adapted for sliding movement within the valve casing and is provided with passageways adapted to form communication between the pipes 42 as previously described. The coreris reciprocated within the casing oy rotation of the stem 224, the stern being provided with an enlarged head 229 rotatable within the valve core but prevented from axial movement with respect thereto by means of the plate member 230. Pipe 42 of the control circuit is also provided with a restriction or orifice section 23|, the function of which will be. later described.

In operation as the motor-24 is started and before the opening of the dispensing valve Il, the main dispensing pump I0 will remain stationary and the auxiliary pumps 4I will be operated as previously described. At this time check valve member 22| is closed so that the control valveI 226 is in its open position as shown in Fig. 34. However, due to the presence of orifice pipe section 23|, a very slight resistance is imparted to the auxiliary pump 4I even when the control is open, the auxiliary pump thus transmitting a small force through the differential to the main dispensing pump I0 tending to drive the same. The dispensing pump will not at this time be driven due to the fact that the nozzle valve I'I is closed, and the small driving force being applied to the dispensing pump is insuilicient 'to cause any tendency of the pump to slip. As the nozzle valve Il is now opened, dispensing pump I0 will be driven slightly causing the initial opening of check valve member 22I. As the check valve opens, control valve core 228 is lowered cutting oi liquid iiow within the control circuit 30 and therebyapplying full driving power to the dispensing pump. Whenl delivering' at partial rates of ilow, check valve 22I and control valve 226 will both be partially open. In this instance no by-pass is provided around the dispensing pump, the calibration of pump I0 being effected by selecting the proper gear ratio for the register driving gears 80 or, if desired, the displacement capacity of the pump itself may be varied.

In Fig. 35 an arrangement substantially similar to that just described isshown except that the surge device I I2 is inserted in the dispensing line between the control check valve 220 and the check valve I9. In operation as the dispensing flow is stopped, the flexible diaphragm l I5 of the surge device will be operated and the air within the dome II3 will be compressed as previously described, and these compression conditions will be maintained after the closing of the nozzle 1 valve due to the check valve I9. Accordingly, 

